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Combining scenario workshops with modeling to assessfuture irrigation water demands
Jean-Daniel Rinaudo, Laure Maton, Isabelle Terrason, Sebastien Chazot,Audrey Richard-Ferroudji, Yvan Caballero
To cite this version:Jean-Daniel Rinaudo, Laure Maton, Isabelle Terrason, Sebastien Chazot, Audrey Richard-Ferroudji,et al.. Combining scenario workshops with modeling to assess future irrigation water demands. Agri-cultural Water Management, Elsevier Masson, 2013, 130, pp.103 -112. �10.1016/j.agwat.2013.08.016�.�hal-00876438�
Paper published in Agricultural Water Management, 2013, vol. 130, p. 103-112 (author’s version)
Combining scenario workshops with modeling
to assess future irrigation water demands
Jean-Daniel Rinaudo1 , Laure Maton1, Isabelle Terrason2, Sébastien Chazot2, Audrey
Richard-Ferroudji 3 and Yvan Caballero1
(1) BRGM, 1034 rue de Pinville, 34000 Montpellier, France. Ph : + 33 4 67 15 79 90. Fax : +33 4 67 64 58 51 (2) BRL Ingénierie, Nimes, France. (3) Cemagref, 361 rue JF Breton, 34033 Montpellier cedex, France. (*) Corresponding author; Email: [email protected]
Abstract
We discuss methodological issues related to the development of long term future agricultural
water demand scenarios. We present the results of original research which combines the use
of scenario workshops with quantitative crop water requirement modeling approaches. Using
a southern France case study, we describe four scenarios, debated with farmers and
stakeholders during workshops and evaluated in terms of total water demand. Results
suggest that socioeconomic evolution could lead to a 40% increase of irrigation water
demand. From a methodological perspective, the research highlights the mutual benefits for
both policy makers and scientists of involving stakeholders in the development of scenarios,
using both qualitative storylines and quantitative modeling tools.
1. Introduction
In regions where imbalances exist between water demand and available resources, medium
and long-term forecasting is a major preoccupation of the water resources and the hydraulic
infrastructure managers. This concern is particularly acute in contexts characterized by rapid
demographic or economic change, which may create urgent needs for new infrastructure
development. Considering the very long lifetime of hydraulic infrastructure (dams, canals
inter-basin transfers), water managers must base their decisions on expected water
demands over the medium and long term (30 to 50 years, depending on the facilities
involved). This proves to be a rather difficult task in basins where agriculture is the main
1
water user, given the high uncertainty attached to future agricultural demands and
technological developments.
Numerous models have been developed for estimating agricultural water demand at the
scale of the region. The simplest modeling approach consists of interfacing agronomic
models with geographic information systems (Hartkamp et al., 1999). Scenarios obtained
from exogenous macro-economic models can be incorporated into these tools to estimate
the long-term development of demand (Weatherhead and Knox, 2000). More complex
approaches have also been developed, involving the combination of agronomic models with
behavioral models designed to represent farmers' technical and economic choices (Maton et
al., 2005; Poussin et al., 2008). Lastly, bio-economic farm models, which use mathematical
programming tools, have been widely used to simulate the development of water demand in
response to changes in farm policy or water pricing. (Varela-Ortega et al., 1998; Bartolini et
al., 2007).
These models are not usually designed to simulate the effects of drastic disruptive economic
structural changes (breakdowns) on irrigation-water demand. They assume, rather, that the
essential structure of the production system remains stable (structure of production and
distribution systems, constraints, price elasticity). However, in a situation of rising uncertainty
- simultaneously economic, social, and climatic - decision-makers can no longer make long-
term water-management plans without taking into account the possibility of such
breakdowns, which can have major impacts (either positive or negative) on water demand,
particularly for irrigation farming. In this paper, we illustrate how foresight (or futures studies)
can offer a complementary framework to the use of models for assessing the need for
irrigation infrastructure development.
Using qualitative approaches, foresight allows accounting for uncertainty through the creation
of highly diverse scenarios concerning the development of the economic environment,
agricultural production, the very structure of the production systems, and the resulting
demand for water. Foresight can help decision-makers explore uncertainty associated to
future developments and assess the consequences of the various strategic choices they
could make. The approach consists of projecting them into a limited number of scenarios,
each of which describes a possible future world. In contrast with predictive approaches,
which seek to identify the most probable future outcome or path, the aim here is "to illuminate
the choices of the present in the light of possible futures" (Godet and Roubelat, 1996). The
expected result is both substantive and procedural: the approach not only enables the parties
involved to make a decision that takes uncertainty into account, but also to construct and
share in a common representation of the uncertainties and temporal dynamics of the
resource-use system that they will have to manage. In turn, this learning experience enables
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a better collective assessment of the infrastructure development options, and more generally
in the water-management policy area.
We are particularly interested in foresight methods that employ scenarios as tools for
exploring the future. These methods, often referred to as "scenario planning", are not a
recent innovation: they were developed in the 1950s in response to the cold war (Kahn and
Wiener, 1967), and have been widely used in the corporate world since the 1980s (Millett,
1988). Scenarios and scenario analyses have subsequently become popular approaches for
use by planners in the area of sustainable development, with applications to multi-sector
economic policy (Rotmans et al., 2000), nature conservation and ecological services
(Peterson et al., 2003; Carpenter et al., 2007), greenhouse gas emission scenarios
(Nakicenovic and Swart, 2000) environmental impact assessment (Duinker and Greig, 2007),
the environmental impacts of agriculture (Poux, 2006; Reed et al., 2009), desertification
control (Patel et al., 2007), and urban development and planning (Street, 1997).
However, the application of these methods in the water sector remains limited. In this area
the scientific literature mainly reflects the results of foresight approaches deployed at the
continental scale (Lake and Bond, 2007), pan-European scale (Kämäri et al., 2008) or the
global scale (van der Helm, 2003). Examples include the development of World Water Vision
(Gallopin and Rijsberman, 2000) and the results obtained from models such as WaterGAP
(Alcamo et al., 2007) and WaterSim (de Fraiture and Wichelns, 2010). Other applications
address the urban uses of water (Phelps et al., 2001; Lienert et al., 2006). However, scenario
planning at the watershed (or aquifer) scale remains little used, while being the scale at
which management are most often considered. The rare examples at this scale are found in
the context of research projects (Hatzilacou et al., 2007) or are applied to a particular
component of water demand (Westcott, 2004).
The limited penetration of foresight methods into the water sector reflects the existence of
unresolved methodological problems. In this article we discuss two of them:
The first concerns the linking of scenario storylines - by nature qualitative - to
quantitative hydrologic and economic modeling tools, on which water managers rely
to take decisions. This integration is often carried out in a semi-quantitative manner
(Kok and van Delden, 2007), which necessarily involves a relative subjectivity when it
comes to quantifying the assumptions made in narrative storylines (Shakley and
Deanwood, 2003). Alcamo proposes an interesting Story-And-Simulation approach,
in which qualitative and quantitative scenarios are linked in an iterative procedure
(Alcamo, 2008).
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The second problem concerns the participatory aspect that must necessarily be a
feature of an exploratory future-study approach. In an environment where predictive
approaches are mainly based on modeling tools and the skills of experts, are
decision-makers ready to acknowledge the value of contributions from users?
Furthermore, are the users capable of freeing themselves from the constraints of the
present and escaping the ultra-local scale, to project themselves into the long-term
and the scale of the region?
We address these two questions by describing a case study conducted in the Roussillon
plain, located in the Eastern Pyrenees County, in the south of France. This is a region where
the future of farming, and consequently future water demands are highly uncertain. We
illustrate the benefits of the scenario method for analyzing uncertainty surrounding future
irrigation-water demands. We describe the participatory foresight approach to exploring the
prospects for agriculture and future water demands.
2. Using scenarios for assessing future water demands
Estimating future irrigation water demand in a river basin requires assumptions concerning
the type of crops and corresponding areas that will be cultivated at the time horizon
considered. This in turn depends on many socio-economic and regulatory factors (both
internal and external to the basin), that are difficult to predict. Assuming that uncertainty
related to this evolution is irreducible, the only option left to water managers that need to plan
long term investment is to explore the diversity of possible future developments to evaluate
the range in which future water demand might be included. The use of simulation models is
one way of exploring future evolution, for instance through Monte Carlo simulation
approaches, with the limitations already mentioned in the introduction (see Graveline et al,
2012 for an illustration). We consider an alternative approach of using qualitative but
comprehensive scenarios for apprehending uncertainty associated with water demands.
The objectives of forming these scenarios include helping decision-makers be aware of the
diversity of possible futures by highlighting the sources of uncertainty over which they have
no control (exploratory scenario exercise). But after this phase, in which the uncertainty is
discovered, scenarios are used to learn how to manage it, ultimately leading to the
development of a strategic action plan. Using scenarios can prepare the actors to confront
potentially unfavorable situations, e.g., under- or over-estimation of future water demands,
which might either destabilize the system technically or financially, or create opportunities.
The scenarios then can play a role in reaching a decision, enabling the actors to re-assess
their strategic choices in the context of uncertainty (van Notten et al., 2003)
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3. Case study and methodology
3.1. Case study area
Our study area is the 700 km² Roussillon plain in the south of France. With an average
precipitation of 570 mm, this region has one of the driest climates in France. The presence of
relatively abundant surface water and groundwater has enabled the development of irrigation
farming (about 15,000 ha irrigated), which produces mainly vegetables (tomatoes,
cucumbers, potatoes, and artichokes) and fruits (peaches, nectarines, and apricots). About
11,000 ha are irrigated by open gravity channels which draw their water from three rivers,
two of which are regulated by dams. The remainder of the irrigated area relies on pressure
irrigation systems of an estimated 4,500 individual boreholes. The rivers' water regime is
typically Mediterranean, with very low water levels in summer.
The doubling of the population between 1954 and 2007 and the development of tourism
along the coast have created a substantial increase in drinking-water requirements. These
needs have been met by increasing withdrawals of groundwater, leading to a lowering of the
water tables and restrictions on the use of boreholes, especially for agriculture.
Implementation of the European Water Framework Directive has led to increases in the flows
of rivers reserved for environmental-protection purposes, to the detriment of irrigation canals.
Several years of drought also have given rise to restrictions on water use.
Long-term predictions of climate change suggest that tensions over water resources are
likely to become more severe. According to the work of the Vulcain Project, by 2030 the
mean annual temperature is expected to increase by 1.5°C, and evapotranspiration by 7%.
Although no significant change in precipitation is anticipated for 2030, by 2050 it should have
fallen by about 15% in the case study area. The Vulcain Project's hydrologists have also
shown that by 2030 river flows are expected to have fallen by about 20% to 40%, with
particularly low levels in summer and autumn (Caballero et al., 2008). These results are
consistent with studies conducted at larger scales (Boe et al., 2009).
The availability of water resources could thus become a major constraint on Roussillon's
agriculture, especially as vineyard irrigation will increase in a drier climate. Agriculture's
economic representatives are therefore calling on public decision-makers to create new
water resources, whether by inter-basin transfers (transfers between local rivers or extension
of the Rhone river water-supply system) or by establishing new storage capacity.
In parallel with this hydro-climatic context, the development of the agricultural base itself
appears relatively uncertain. Since the areas irrigated, the number of operations, and the
value of their production have fallen regularly for several decades (33% of farms vanished
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between 2000 and 2007, representing at least 10% of the agricultural area1), we may
reasonably wonder whether the water demand for irrigation is indeed going to rise. It is in this
context that we explore the future of agriculture and the demand for irrigation water, by
applying the principles of the scenario method described in the preceding section.
3.2. Methodology
The foresight methodology includes four steps. The first is identifying the driving forces of
change and the sources of uncertainty concerning the development of irrigation farming by
2030, by drawing on a group of experts and actors in the agricultural sector. The second is
preparing four contrasting scenarios for the development of agriculture, which are then
opened for discussion (Step 3) during workshops organized separately with experts and
farmers. The fourth step is that of developing a model for quantifying the irrigation-water
demands associated with the scenarios, as reviewed and corrected by the actors during the
workshops. Workshops were organized in 2009 and the rest of the study completed in 2010.
3.2.1. Identification of driving forces and uncertainties
The driving forces and uncertainties were identified by eleven experts from Roussillon's
agricultural sector, during a preliminary half-day foresight workshop. The expert group
included representatives from the farmers’ associations, market operators, the
administration, and a few scientists. Experts were identified based on a stakeholder analysis
conducted as part of a previous project (Aunay et al., 2007; Montginoul and Rinaudo, 2010).
During this workshop we asked participants to identify the main factors that had determined
the development of agriculture over the last 20 years, considering both factors external (e.g.,
the entry of Spain into the Common Market in 1981) and internal factors (e.g. development of
water resources, urbanization, and the abandonment of farmland). Participants were then
invited to discuss the factors most likely to affect the future development of agriculture by
2030 and to list the main sources of uncertainty involved. In parallel with this workshop,
discussions were also held with about twenty farmers from the study area2, to complement
1 Source : AGRESTE (French Agricultural Statistics), Recensement Général Agricole for 2000 (Farm
Census 2000) and Enquête Structures for 2007 (Farm survey, 2007).
2 Farmers were recruited with the help of two local institutions, the Chamber of Agriculture and an
Association for the development of Organic Farming (CIVAM Bio 66). Selection criteria included the type of production (vine, fruits and/or vegetable), the geographic location, type of water resources used (canal irrigation or groundwater), farm size and the age of farmers. Overall, farmers who were finally recruited were of two different types. A first type consisted of farmers who define themselves as true entrepreneurs, with a real capacity to adapt their technical and economic choices to a changing environment. A second type consisted of farmers already engaged in the search of alternative farm models (e.g. organic farming, producing non regional crops) claiming greater social recognition of agriculture for the many roles it plays beyond food production (e.g. environmental externalities, territorial development, etc.). The team failed in recruiting many other farmers who did not perceive
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and enrich the experts' regional outlook with the individual plans for the future that the
farmers might have at the level of their own operations.
3.2.2. Development of contrasting scenarios
The scenarios were focused on agriculture and its water requirements in 2030, and only
briefly describe the chain of events leading from the 2007 reference situation to that year.
Each of the four scenarios was framed in a different external context which was considered
to be imposed to the territory itself and not debatable by the stakeholders. Participants were
asked only to discuss choices related to factors under local control. Whereas the external
assumptions of the four scenarios were drawn from those developed by the La Bussière
Group at the national level (Poux, 2006), the narrative description of future agriculture at the
local level was based on the views presented by farmers and on imagined components
introduced by the authors. The scenarios were clearly designed – and presented as such to
stakeholders – as a source of inspiration for the process, not as scientifically sound
projections.
3.2.3. Scenario workshops
Although the scenario-workshop method usually involves the mixing of policy makers,
business representatives, experts, and citizens (Street, 1997; Andersen and Jaeger, 1999;
Lienert et al., 2006; Hatzilacou et al., 2007), we decided to set up separate groups for
different groups. We also opted for smaller groups (five to eleven persons) in contrast to the
scenario groups described in the literature, where each workshop includes between 25 and
40 persons (Andersen and Jaeger, 1999; Hatzilacou et al., 2007; Patel et al., 2007). The
existing expert group (11 participants) was therefore supplemented by three groups of
farmers. This methodological choice was adopted to overcome the mistrust that
characterizes relationships between the farmers and public-sector experts; the creation of
homogeneous groups was perceived as facilitating the emergence of mutual trust. In each
group of farmers, the three main production activities (wine-growing, fruit, and vegetables) of
the traditional sector and of organic farming were represented, as well as the area's
geographic diversity. One of the groups consisted mainly of young farmers (under 40 years
old) who are likely to have a different view of the outlook for 2030, a time when they will
probably still be actively involved. We met separately with each invited farmer before the
workshop was convened to present the project’s objective and to assess their motivation to
participate. They then received by mail a narrative outline of the scenarios (two pages of text
per scenario).
how their lay vision could contribute to the definition of long term public policies or because they felt that the future would be imposed on them by external forces which lie out of their control.
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Discussions of the scenarios took place during workshops held over a half-day period in the
evening (6 to 11 PM), and including a meal for the farmers. The workshops were organized
as follows. After a brief presentation of the workshop’s objectives, a discussion leader
presents the first scenario, using a poster as support. The participants are invited to
comment individually during a round-table session before discussing any confronting points
of view. During this discussion the leader refocuses the debate on the implications of the
scenario for water management.
This sequence is then repeated for each scenario. The participants are invited to prepare
individual rankings of the four scenarios according to their probability and desirability.
Comparison of these pictures of the probable and desirable futures gives rise to a final group
discussion. The discussions are recorded to enable subsequent detailed study of the
observations. In the next few days after the workshop, telephone interviews are conducted to
obtain the participants' opinions concerning the working method and the content of the
discussions. A four-page workshop summary report is sent to the participants.
Since workshops were organized in a research context, the objective was not to reach a
consensus or to prepare concrete decisions. Instead, the aim was to encourage the
expression of various pictures of the future, and to facilitate the mutual discovery of differing
points of view concerning future evolution of agriculture and associated irrigation water
demands.
3.2.4. Quantification of scenarios
The two principal scenarios (the probable and the desirable) which emerge from the
workshops are expressed as quantified assumptions, in terms of cultivated areas, irrigated
areas, cropping patterns, and irrigation practices.
A model designed to quantify the irrigation water requirements is then developed for each of
the eleven watersheds in the study area. For each catchment area j, the model calculates the
water withdrawal WWj carried out by the farmers, taking into account (1) the climate in the
watershed j (which determines the unit crop water requirement CWRi,j for each crop i, (2) the
areas farmed Si,j for each crop in the watershed j, and (3) the irrigation technologies, which
are characterized by an efficiency coefficient Ej.
The model is applied to each of the eleven main sub-catchment areas for which the project
team has determined a mean technical efficiency Ej for the systems irrigated, the climate,
and the areas under cultivation. The model is calibrated by comparing the results of the
simulations with the observed data, and then used to perform simulations. The crops water
requirements are calculated as follows, in accordance with FAO methodology (Allen et al.,
1998):
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8
t
d
jdjdjddiji RAWPETKcCWR1
,1,,,),( .;0max
Where:
CWRi,j is the crop water requirement of crop i in climatic catchment j;
Kci,d is the crop coefficient of crop i for decade d and climatic catchment j;
ET d,j is the evapotranspiration for decade d in climatic catchment j;
P d,j is the total precipitation during decade d in climatic catchment j;
RAWd-1, j is soil Readily Available Water during decade d-1 in catchment j.
The water requirements of the crops are calculated at a ten day time step for 13 climatic
zones, using values of Kc appropriate to the terrain3. The total demand for irrigation water is
calculated for the two scenarios, for each of the 35 climate years from 1971 to 2005. We then
look at the statistical distribution of the results to estimate the value which only exceeded 1
year out of 5 (5 years return high water requirements).
4. Results of the scenario workshops
4.1. Identification of the main sources of uncertainty
During the first foresight workshop the experts identified the main sources of external and
internal uncertainty in the region that might have an impact on future water demands. The
nine main factors listed in Table 1 provide a good illustration of the wide range of driving
forces that may need to be considered when attempting to assess future demands for
irrigation water in a region subject to many sources of transformation. The workshop
contributed to the construction of a common understanding by participants of the role of
these external and internal factors. For the research team, the workshop identified the
internal driving forces, as some of them had not been clearly identified through previous field
work (factors 6 and 8 of table 1 for instance).
3 In the method selected (crop coefficient approach, the crop evapotranspiration (ETc) is calculated by
multiplying the reference crop evapotranspiration (ETo, climatic data) by a crop coefficient, Kc. This Kc coefficient represents an integration of the effects of four primary crop characteristics that determine crop evapo-transpiration: (i) crop height; (ii) albedo (reflectance) of the crop-soil surface; (iii) canopy resistance and (iv) evaporation from exposed soil (Allen et al, 1998). Kc values for the case study have been established by agronomists of BRL, an irrigation company operating in the area.
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Table 1: Principal factors of change identified by the actors in the first workshop.
4.2. Scenarios discussed
The sources of uncertainty identified by the actors, together with several other factors
described in the literature4, were employed to define four contrasting scenarios for the
development of agriculture in Roussillon. These scenarios are set out below and summarized
in table 2.
4 Literature concerning possible future evolution of: Common Agricultural Policy; fruits, vegetable and
vine markets; agricultural demography; local urban development; agronomic innovation.
Table 1: Principal factors of change identified by the actors in the first workshop.
Factors of change Impact on agriculture
Impact on irrigation
External factors
1 Reduction in subsidies from the Common Agricultural Policy
decline -
2 Strengthening of environmental regulation: higher environmental water allocation, increased limitations on irrigation water use
decline -
3 Increases in the cost of energy and of international long-distance transport, decreased competition from far-distant countries, enhanced competitiveness of local agriculture
revival +
4 Reform of French regulation: irrigation of vineyards authorized
revival +
5 Urbanization, urban sprawl and loss of farmland , partly due to the growing influence of Barcelona (commuting population)
decline
Internal factors
6 Development of Saint Charles International fruit & vegetable market business plateform (rail-road transport)
revival +
7 Dismantling of irrigation associations, breakdown of gravity irrigation canals (partly due to urban sprawl), resulting in increased individual groundwater use
decline -
8 Local policy encouraging the recruitment of young farmers to replace very high number of retirees expected in the coming decade
decline -
9 Local agricultural policy encouraging the production of environmental services by agriculture (protection of landscape, biodiversity, groundwater recharge through irrigation).
revival = or +
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Paper published in Agricultural Water Management, 2013, vol. 130, p. 103-112 (author’s version)
Table 2: Overview of scenarios presented to workshop participants.
Driving forces Current situation S1 – Ultra-competitive agriculture S2 – Two tiers agriculture S3 – Regional development S4 – High environmental performance
Agricultural market
Liberalization trend. Increasing international competition & import of agricultural products on EU market. Petrol price : 40 to 140 $/barrel
Strong competition from non-European countries (Latina America) due to extreme liberalization of trade and low petrol price (75$/barrel).
Very low agricultural prices determined by world market
Consumers mostly purchase cheap standardized food product in hard discount supermarkets (origin of products does not matter)
Moderate international competition due to liberalization and intermediate petrol price (125 $)
Market segmentation: cheap & standard food products (S1) for supplying industrial / discount supermarkets.
Local higher quality products sold on regional market (direct sales, specialized retail shops)
Trade liberalization limited by strong EU norms (quality of EU products slightly higher than on international markets).
Emergence of high quality / high added value food products for niche markets. Export boosted by regional marketing policy
For cheap products, international competition reduced due to high petrol price (150$/barrel) &transportation cost
Access to the EU market is restricted by health regulation (zero pesticide products).
EU food products are sold at price that exceeds those on the world market.
International competition limited by high petrol price (150 $/barrel). EU reduces its agricultural exports.
European Common Agriculture Policy (CAP)
Total CAP budget = € 12 billion
Current policy dismantled (end of 1rst & 2
nd pillar of the CAP). CAP limited to
investment subsidies granted to large farms. Total CAP budget = € 3 billion (€10 000 / labor unit)
Strengthening of CAP, two tiers approach: for large farms, investment subsidies; for small farms, subsidies for environmental services Total CAP budget = € 7 billion (€25 000 / labor unit)
Transferred to Regions which develop their own policy to maximize their competitive advantage. Total CAP budget = € 6 billion (€11 600 / labor unit)
Subsidies coupled to production again. Total CAP budget = € 12 billion (€12 000 / labor unit)
Social demand for agricultural products and services
Food purchase represents 15% of households’ budget. 13% households purchase food in hard discount supermarkets.
Cheap food product (food purchase = 10% of households’ budget). 60% of households purchase food in hard discount supermarkets. Environment is not a key preoccupation. Agriculture, a business as any other.
Cheap food product & environmental services. Two forms of agriculture coexist. Households willing to spend 15% of their budget for food purchase.
High quality agriculture contributes to the development of the regional repute, together with tourism, natural assets
Agriculture contributes to employment and the chain of value creation
Households willing to spend 17% of their budget for food purchase.
Social demand for food safety &environmental quality. Agriculture considered as essential for the mainstay of economic activity in rural areas. The agricultural sector is an attractive sector for skilled labor force
Food purchase = 22% of households’ budget.
Economic structure of the agricultural sector
660 000 farms, 1 million labor units in France
4000 farms in the case study area
Large commercial farm with high technology / high capital needs. Intensive use of seasonal foreign cheap labor. Current family farms, unable to compete, disappear.
120 000 farms in France, 300 000 labor units. 750 farms in the case study area
Large commercial farms (33 000 farms, 94 000 labor units) coexist with small/medium family farms (183 000 farms, 260 000 labor units)
1500 farms in case study area
Strong vertical integration (farms, small food & beverage industry, marketing) through new forms of cooperatives, supported by a voluntarist regional policy (technical support, funding of integrated projects). 400 000 farms in France. 3000 farms in case study area
Small-medium farms. high technology/ high labor /moderate capital needs
New forms of cooperatives for marketing / products transformation
500 000 farms in France, 1 million labor units. 4500 farms in case study area
Cultivated and irrigated area
Urban sprawl & decrease of number of farms -> strong reduction of cultivated area. Improvement of irrigation performance (drip irrigation) -> overall decrease of irrigation demand
Modernization of irrigation practices (-15% water use per hectare). Increase area of irrigated vines. Overall, stabilization of water demand
Construction of a regional aqueduct, water supply unlimited at affordable price. Increase in irrigated area => water demand increases.
Improvement of irrigation technologies offset by increased irrigated area. Overall, increase in water demand.
Paper published in Agricultural Water Management, 2013, vol. 130, p. 103-112 (author’s version)
Paper published in Agricultural Water Management, 2013, vol. 130, p. 103-112 (author’s version)
4.2.1. Scenario 1: Ultra-competitive farming
In the context of a liberalization of global trading, the Common Agricultural Policy is
dismantled by 2030. This development is partially offset, in France, by the implementation of
a national policy of competitive modernization of agricultural businesses (investment grants).
Moreover, purchasing power is the main preoccupation of the French, who buy their
groceries in hard-discount retail chains. Product standardization increases. In this situation,
only the very biggest fruit and vegetable production systems in the Roussillon survive, and
these are partly owned by outside investors. In wine-growing, barely a hundred large
producers and a few restructured cooperative cellars are operating on an area one quarter of
what it was in 2010. The family farm has almost vanished. Growing urbanization of the land
intensifies the effects of this economic development. Gravity irrigation systems are
progressively dismantled and replaced by boreholes tapping shallow and deep aquifers.
Overall, demand for irrigation water declines sharply.
4.2.2. Scenario 2: Two-tier farming
In 2030 two kinds of farming coexist in the Roussillon: 150 to 200-ha agricultural enterprises
that compete in global markets, producing mainly bulk quantities of cheap fruit and
vegetables; and multipurpose 50-ha farms, most of which are strongly subsidized for the
production of environmental services, with production contributing to income in only a
secondary fashion. The new Common Agricultural and Rural Policy (CARP) provides
assistance to both of these farming activities through separate subsidy systems. Agro-
tourism - whose development is strongly supported by both the Region and the County - has
become a major source of outside income for the multipurpose farms. Population growth is
divided equally between the hinterland and the plain, and poses no threat to farmland. In
mountainous areas, the farms benefit from additional support systems, such as grants for
transhumant droves, and local landscape maintenance contracts, operated by the
communes. Organic farming is occupying greater areas (20%), particularly within
multipurpose operations which benefit from eco-conditional grants and a buoyant market. As
regards water management, now that the multiple uses of irrigation canals have been widely
demonstrated (groundwater recharge, urban water supply, storm water evacuation during
heavy rain periods), their agricultural applications are being promoted by public grants.
Withdrawals of groundwater for farming purposes are being regulated and progressively
reduced, while the management of existing dams has been optimized, increasing the
quantities available for irrigation. Overall, agricultural water demand remains at 2010 levels.
4.2.3. A regionalized agricultural development in Europe
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By 2030 the regions have become the places where new farm policies are developed. Using
European Community budgets allocated on the basis of criteria that combine total operated
area, rural population, level of economic development, and environmental situation, each
region applies itself to optimizing its comparative advantages. The Languedoc-Roussillon
Region has invested in the development of a diversified agriculture with a very high added
value, based on high-range productions aimed at European and world markets. It has
created a system of training schemes for farmers, contributed to the establishment of new
regional food / beverage industries and distribution chains with good vertical integration, and
very actively supports the creation and promotion of new brands and controlled appellations.
The "Sud Intense: colours - tastes - lands" brand, created by the Regional Agency for the
Promotion of Local Products (founded in 2020), has acquired an international reputation that
encourages the export of fresh farm produce (fruit and vegetables) and their transformed
products (wine, olive oil, crystallized fruit, etc.). The balance of power between distribution
and agriculture has shifted, to the advantage of the producers. After a long period of crisis,
areas occupied by vineyards are again increasing, reaching 2010 levels by 2030.
Arboriculture has diversified, with the return of the olive tree (controlled appellations oils), the
cherry and selected older varieties of apricot and peach. Moreover the Roussillon population,
now highly urbanized, is voicing vigorous social demands concerning protection of the
environment, the quality of life, natural resources, and the landscape. These demands are
leading to the signing of contracts between farmers and local authorities, under regional
umbrella projects. These contracts address "the introduction or continuation of activities
contributing to the economic, social, and environmental development of farming". The
demand for irrigation water experiences a significant rise, which can be met by larger
withdrawals from existing dams, in particular from Villeneuve-de-la-Raho reservoir, which
has been under-used for many years. Additional water resources are also developed.
4.2.4. Scenario 4: High-Performance Environmental Farming
Environmental expectations govern the demands of European and French society. The use
of pesticides is totally banned since 2022. A model of farming certified as "High-Performance
Environmental Farming" has been progressively imposed. Inspired by organic farming, but
with a somewhat relaxed version of its technical constraints (fertilization, use of drugs in
rearing), HPE farming retains the prohibition against pesticide use. The Roussillon has
positioned itself as a pioneer in the development of HPE by using its three major assets: a
highly-favorable climate (hours of sunshine, and wind) ; experience in organic farming, which
has been growing since the 2010-2020 period ; and the proximity of the Montpellier
agronomic research centers. A European Agricultural Policy along the lines of the 1960s one
has been established: it encourages HPE production through production subsidies, finances
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investments for the restructuring of traditional farming on the HPE model and for training and
research. It also provides financial support for the transformation of downstream distribution
chains (agro-processing industry and product-packaging facilities). The distribution of food
products follows a model completely different from the dominant model of the 2010-2020
period. Products are less standardized (more varied grading), and they travel shorter
distances, both because of the higher cost of transport and because of the constraints
imposed on packaging (requirement for recovery and recycling). In addition, the requirement
for dual display of both producer and consumer prices has led to a sharp drop in distributor
profit margins. Finally, since the EU imposes higher environmental standards on food
products (zero pesticide), the prices establish themselves above world prices of conventional
products. Overall, agriculture in the Roussillon experiences unusually dynamic growth in
terms of the area farmed, the recruitment of young farmers, new jobs, and added value. As a
direct consequence, the consumption of irrigation water rises very steeply.
4.3. Assessment of the scenarios
The discussions that took place during the four workshops mainly concerned the future of
farming, demand for water being seen as a consequence of socio-economic development.
After a discussion of each scenario, the participants were asked to provide individual
rankings of the scenarios from more to less probable, and from more to less desirable.
Figure 1 summarizes the classifications made by the professional experts (11) and the
farmers (15).
Only 8% of the participants want to see the outcome described in Scenario 1 (ultra-
competitive farming), although 33% of them think it will probably come to pass. This scenario
is perceived as an alarmist but realistic portrayal of the situation that could result from a
combination of unfavorable changes in the overall economic environment, and a lack of
activist projects from the profession itself. A danger of irreversibility is associated with this
scenario, since a declining agriculture could lead within a few years to a complete
dismantling of land-ownership structures, of irrigation systems, of the farmers' technical
expertise, and more generally of the human and social capital (Figure 2). The participants
confirm that this scenario would lead to a fall in the demand for irrigation water.
Scenario 2 (two-tier farming) is the outcome judged to be the most probable (by 54% of
participants) while not being perceived as desirable (36%), in particular because it makes
farming more dependent on subsidies than in the 2007 reference situation. However, the
participants believe that this scenario represents a transition situation that could last for only
a brief time before evolving either in the direction of Scenario 1, or towards Scenario 3 or 4
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(Figure 2). Accordingly, we did not use this scenario to quantify the requirements for water in
2030 in the continuation of the study.
In contrast, Scenarios 3 and 4 were perceived overall as representing goals that were
desirable to reach (72% and 80% of participants), especially as they enable farmers to live
off their earnings, to create added value and employment, and to contribute to regional
economic development. The participants suggested that the assumptions derived from these
two scenarios could be combined. However, these scenarios are considered to be less likely
to happen than the two others (46% and 38% judge S3 and S4 to be probable) because they
assume a high level of activism on the part of the political and economic actors in the
European, national, regional, and local arenas. Both of these scenarios would lead to an
increase in the demand for irrigation water.
At the conclusion of the workshops, two scenarios were adopted for the quantification of
water requirements: Scenario 1, which assumes an overall decline of farmland, leading to a
probable reduction in water demand; and a hybrid scenario combining the main assumptions
of scenarios 3 and 4, which assumes a revival of farming activity and an increase in water
demand.
Figure 1: Workshop participants' perceptions of the desirable and probable natures of
the four scenarios discussed
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Figure 2: Perceptions of the possible paths associated with the various scenarios
5. Quantification of irrigation water demand
5.1. From narratives to quantified scenarios
The text describing the scenarios, distributed to workshop participants, contained a table
summarizing underlying assumptions (crop areas, irrigated areas, and number of farming
operations). These assumptions were submitted to all workshop participants for their review
but only experts were able to critically discuss them. The final decision concerning these
assumptions was taken by the research team, in light of the views expressed in the
workshops. The requirements for irrigation water were estimated on this basis, using the
model described above and for a dry year context (Table 3). Changes in irrigated area which
are assumed in scenario “3+4” are fully compatible with local land, water and economic
constraints. Overall, the new dynamics assumed in scenario 3+4 would bring agriculture
back to its 1990’s level in terms of area, but with a higher added value. Cooperatives would
not face any problems to transform and commercialize the additional fruit and vegetable
production and the increased production would not be significant enough to impact prices on
the European market. Also note that the significant increase in irrigated vineyards assumed
in the “3+4” scenario does not correspond to newly planted areas but to the conversion of
existing vineyards into irrigated vineyards.
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Table 3: Quantification of irrigated areas by crop and irrigation-water requirements
(allowing for irrigation efficiency) for two scenarios in dry year context.
5.2. Simulated impact of scenarios on water demand
In the first scenario, irrigated crops areas decline by about 15%, but this is offset by an
increase in vineyard irrigation, which is considered to be a strong trend. Overall this scenario
leads to a decline of about 4% in water withdrawals in the study area during the irrigation
period (April-October). This decline is relatively small in comparison with the opinion
expressed by the workshop participants. In Scenario (3+4), there is a vigorous renewal of
farming, leading to an increase in the areas under fruit (+37%) and vegetables (+24%). This
scenario leads to an increase of about 43% in withdrawals of water during the irrigation
period, part of which is also due to vineyard irrigation.
A more detailed examination of the time distribution of water demand in Scenario (3+4)
suggests that the stresses are likely to become particularly acute during the summer. Water
requirements will increase by about 50% from June to August, going from 20 to 30 million m3
in June and July, and from 30 to 45 million m3 in August (Figure 3).
Reference situation
S1: ultracompetitive
farming
S(3+4): Regionalized development & high
performance environmental
in ha in % of total agricultural
area
in ha variation in % of
reference
in ha variation in % of reference
Total irrigated area 15384 100% 17277 +12% 24580 +60%
peach 8175 53% 6949 -15% 9352 +14%
apricot 1330 9% 1131 -15% 1596 +20%
cherry 547 4% 465 -15% 602 +10%
apple 98 1% 83 -15% 196 +100%
olive 105 1% 95 -10% 210 +100%
vegetables 3667 24% 3080 -16% 4557 +24%
vineyards 534 3% 4731 +786% 6800 +1173%
grasslands 913 6% 730 -20% 867 -5%
cereals 15 0% 14 -10% 400 +2567%
Estimated crop water requirements
(in million m3)
87.3 million
m3
-- 83.4 million
m3
-4.5% 124.7 million
m3
+42.8%
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Figure 3: Estimated monthly water demand in the 2007 reference situation and under
Scenarios 1 and (3+4).
Similarly, examination of the spatial distribution of future water demand shows that the
growth in requirements associated with Scenarios 1 and (3+4) will mainly occur in a few sub-
basins. In both scenarios the development of vineyard irrigation will have particularly severe
consequences in the two northern sub-basins (Agly and Verdouble) where due to the
development of vine irrigation, water demand will increase by of 248% and 548% (Scenario
1) and by 274% and 650% in Scenario (3+4) (Figure 4). These new demands are likely to be
partly satisfied by a reservoir located on the Agly river which is not yet fully used. New water
demands associated with increased orchard area in the central Têt valley will be more
difficult to meet, given the level of tension that already exist in that basin. And new demands
in the Roussillon plain (west of the area) will probably lead to increased groundwater
pumping in the shallow aquifer, with possible over-exploitation risks.
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Figure 4: Variation of water demands for irrigation in each of the 11 sub-basins for
Scenario 1 and Scenario (3+4), in % over the 2007-2030 period.
6. Discussion
6.1. Stakeholders’ evaluation of research
The research protocol was evaluated by means of telephone debriefing interviews with all
workshop participants. The positive feedback received shows that farmers, experts, and
institutional representatives alike appreciated the opportunity for debate offered by the
scenario workshops, confirming the conclusions of other similar experiments (Hatzilacou et
al., 2007; Patel et al., 2007).
All of the participants said they found the discussion time valuable. The workshop offered
them a unique opportunity to think about the consequences of long-term changes, something
which neither farmers nor institutional experts have time to do, being trapped in their present
constraints and short term objectives. Another key motivation for participants was the
opportunity offered by the workshop to listen to each other’s opinions, in a strategic behavior-
free context. This was emphasized by the institutional experts, who are used to meeting in
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arenas where they have to defend vested interests and entrenched positions dependent on
their institutions, with regard to short-term political and economic issues. The enthusiasm of
the participants was subsequently confirmed by their participation in two additional series of
workshops which were organized six and twelve months later to discuss the impact of
climate change on agriculture, water management, and water-allocation mechanisms in a
world with ever-scarcer water resources (Rinaudo et al., 2012).
Workshop participants appreciated the neutrality of the research team, which was operating
under EU and national funding, independently from any local stakeholder. This was clearly
expressed at the end of the workshops as they rejected our proposal to revise the scenario
narratives based on workshop output. By doing so, scenario narratives would have become
an official reference with a possible risk of interference in the policy making process. To
remain neutral, researchers were invited to keep away from any kind of normative approach.
The situation would have been much different if workshops had been organized under the
patronage of a local institution (Chamber of Agriculture or Water Commission for instance).
Concerning the use of pre-established scenarios, several participants (both experts and
farmers) mentioned they found it difficult, at the beginning of the workshop, to grasp how to
use scenarios as a basis for discussion. In fact, most of them used the time devoted to
discussion of the first scenario to express their feelings on how things were likely to evolve
rather than to describe how agriculture would evolve if the assumptions related to external
conditions were to turn out as described in Scenario 1. However, the objective of the
scenario exercise became clear after discussing the first scenario. Overall, participants found
the four scenarios useful as a basis for discussion, recognizing that exploring possible
futures would have been difficult without such support. Most of them found the scenarios
sufficiently different, although a few farmers criticized the research team for its lack of
imagination: they would have expected at least one scenario to include, for instance,
assumptions related to a world food crisis. They appreciated receiving scenario descriptions
in advance and found that the two-page format was appropriate. A small number of
participants admitted that they did not have time to read the documents before the workshop.
6.2. Difficulty of linking the narrative storylines with models of water demand
The experts as a group found the process of quantifying the assumptions for each scenario
very difficult, while the farmers were unwilling to discuss these assumptions. This constituted
a setback for our working method, which consisted of linking the scenario workshops to
models of water demand. The discussions aroused by the storylines mainly addressed the
causal links between the factors determining the dynamics of the system studied, and the
state of that system. Quantification was then perceived by the participants as a highly
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reductive exercise, in opposition to the intellectual freedom associated with the process of
exploring possible futures. Ultimately, then, it came down to the researchers leading the
foresight exercise to quantify the assumptions, in light of the qualitative viewpoints expressed
in the workshops.
To make it easier for workshop participants to grasp the quantified assumptions, it would
have been necessary to formulate these assumptions at a more local scale: the eleven sub-
catchment areas depicted in figure 4 above. This is in fact the scale at which the farmers and
experts are able to formulate hypotheses of the growth or shrinkage of the areas under
cultivation, by incorporating into their analysis their knowledge of the human, pedologic,
climatic, and other constraints. It is at this same scale that it would have been necessary to
refine the assumptions concerning the improvement of irrigation efficiency, examining
scenarios for modernizing the infrastructure of irrigation area by area. To perform this
quantification would have required the establishment of four or five geographic working
groups involving local experts.
6.3. The added value of scenario workshops
By combining modeling with a participatory approach, the scenarios developed in this
research have become a tool that can improve dialogue between stakeholders and
scientists. For engineers and water resource modelers, what really matters is the set of
quantitative assumptions associated to each scenario (the term scenario is indeed used as a
synonym for “forcing data set”). For stakeholders, the key components of the scenarios are
assumptions related to driving forces which are depicted in a consistent vision of future
development of irrigated agriculture. Once the quantitative and qualitative facets of the
scenarios have been connected, the two communities can really dialogue on the
consequences associated to different future developments.
More generally, the workshops enabled the actors to construct a shared knowledge base
concerning the uncertainties to which agriculture is exposed. This knowledge base is a
prerequisite for a collective discussion of the solutions that might be applied to deal with
possible water-resource availability problems.
The workshops' contribution extends far beyond its initial scope. By exploring scenarios that
represent both feared and desired developments, the workshops have drawn attention to
priorities for actions in the field of agricultural development as well as in water management.
As regards water management, the workshops have highlighted a certain consensus around
the following ideas: (1) priority must be assigned to maintenance of the canal system and of
the associations that manage it; (2) more efficient management of the existing hydraulic
infrastructure of dams and canals should go some way towards meeting an increase in
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demand; (3) the creation of new water resources (small reservoirs) might be necessary in
certain areas, but the development of agriculture will not require the construction of a major
new dam or the construction of an inter-basin pipeline. This finding illustrates the manner in
which scenario workshops can contribute to starting a debate on the future aspects of
management at watershed scale.
6.4. Methodological conclusions and recommendations
Our experience confirms the pertinence of some of the methodological choices made to
engage stakeholders in a debate that does not relate to immediate sources of concern: (1)
farmers and experts can contribute actively to the exploration of alternative futures even if
the participation process does not lead to a decision; (2) lay participants (farmers) are able to
explore futures 30 years ahead even though their time horizon is usually much shorter; (3)
the use of a limited number of predefined scenarios facilitates the stakeholders’ exploration
of possible futures; (4) the establishment of separate groups for farmers and institutional
representatives seems to be a necessary condition for enabling free expression and debate
involving diverging opinions (5) the recruitment of participants should be guided by the
participants’ motivation and willingness to invest time and energy in the participation process
rather than by considerations of representativeness; (6) the choice of a deliberative format
aiming at the comparison of opposing visions enables fruitful discussions even if it does not
lead to a consensus.
In conclusion, our experience suggests that scenario workshops can usefully supplement
modeling methods in predicting the long-term development of irrigation-water demand.
Moreover, these studies enable the involvement of the actors in identifying the issues
associated with the growth of irrigation, in accordance with Article 14 of the European Water
Framework Directive.
Acknowledgements
Our research was financially supported by the French Research Agency (ANR) as part of the
VULCAIN ANR project. We also received financial support from the Ministry of Ecology and
Sustainable Development under the AQUIMED project (Circle-Med Era Net initiative). We
acknowledge the very useful comments from two anonymous referees and from the editor
Dennis Wichelns. The usual disclaimer applies.
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